DE102013226418B3 - ultrasonic motor - Google Patents

Abstract

The invention relates to an ultrasonic motor comprising a piezoelectric ultrasonic actuator having four friction elements arranged thereon, a friction surface in frictional contact with the friction elements, and an electrical excitation device, wherein the ultrasonic actuator is in the form of a ring or a hollow cylinder having an inner peripheral surface, an outer peripheral surface and two flat end faces connecting the inner and outer circumferential surfaces, wherein the four friction elements are arranged on one of the end faces of the ultrasonic actuator at equidistant spacing with respect to the circumferential direction, so that in each case two of the friction elements lie diametrically opposite each other, and the ultrasonic actuator comprises twelve equal circumferential sections, each having a generator for an acoustic standing wave to be formed in the ultrasonic actuator and the deformations of the ultrasonic actuator caused by the standing wave to deflections of F and at least one exciter electrode, at least one general electrode or a section of a general electrode and one between the excitation electrode and the general electrode or the section of the general Having arranged electrode electrode layer of piezoceramic.

Description

The invention relates to an ultrasonic motor according to claims 1 to 5.

From the US 6,765,335 B2 an ultrasonic motor is known with which by means of an ultrasonic actuator, a linear Einkoordinatenbewegung the driven element can be realized. To realize a two- or three-coordinate movement corresponding ultrasonic motors require two or three independent ultrasonic actuators (see, for example, the EP 2 258 004 B1 or the US 7,635,940 B2 ).

From the DE 10 2012 201 863 B3 is with the local 4 a hollow cylindrical ultrasonic motor is known, which sets the driven element in a rotational movement.

From the DE 195 22 072 C1 is with the local 18 a hollow cylindrical ultrasonic actuator for a corresponding ultrasonic motor is known which also sets the driven element in a rotational movement.

The DE 10 2008 023 478 A1 shows with the local 8th and 9 a hollow cylindrical ultrasonic actuator for a corresponding ultrasonic motor, which represents a linear drive.

The object of the invention is to provide an ultrasonic motor which is able by means of only one ultrasonic actuator to generate a two- or three-coordinate movement of the element to be driven by it.

The object is achieved by an ultrasonic motor according to claim 1, wherein the subsequent dependent claims comprise at least expedient refinements and developments.

Thus, an ultrasonic motor having a piezoelectric ultrasonic actuator in the form of a ring or a hollow cylinder having an inner circumferential surface, an outer peripheral surface and two planar end surfaces interconnecting the inner and outer peripheral surfaces, wherein four friction elements are disposed on one of the flat end surfaces. The friction elements are distributed over the circumference of the ultrasound actuator or the end face distributed in equal distances from each other (that is, equidistant). In other words, a circumferential angle of 90 ° lies between two adjacent friction elements, so that in each case two of the four friction elements lie diametrically opposite one another (that is, with a circumferential angular distance of 180 °). The friction elements are in frictional or operative contact with a friction surface of an element, such as a Friktionstisches to which they are resiliently pressed.

In addition, the ultrasonic motor according to the invention comprises an electrical excitation device. This is intended for electrical connection to exciter electrodes and general electrodes or to a general electrode of the ultrasound actuator, wherein the exciter electrodes together with the general electrodes or with the general electrode and a piezoelectric material arranged between the excitation electrode and the general electrode, a generator for form an acoustic standing wave to be formed in the ultrasonic actuator. Overall, the ultrasonic actuator has twelve equal and distributed over the circumference of the ultrasonic actuator generators. Each generator is part of a peripheral portion of the hollow cylinder or ring, wherein each peripheral portion forms a partial hollow cylinder.

By appropriate electrical excitation of the generators via the electrical excitation device is formed in the ultrasonic actuator, which is a wave resonator, an acoustic standing or deformation wave, and caused by the standing wave deformations of the ultrasonic actuator lead to corresponding deflections of the friction elements on or along a End face inclined trajectory and / or a direction substantially perpendicular to the end face (transverse movement path), wherein the inclined trajectory having a longitudinal or tangential component and a transverse or axial components, and the longitudinal or tangential component is substantially parallel to the friction surface. In this case, a movement perpendicular to the friction surface (z-direction) can be generated by the deflection of the friction elements in the direction substantially perpendicular to the end face (ie on the transverse movement path), while due to the deflection of the friction elements on or along the inclined path to the end face movement along the friction surface (xy plane) can be generated.

Thus, the ultrasonic motor according to the invention with only one ultrasonic actuator both a two-coordinate movement in a plane (the x-y plane) generate, as well as a three-coordinate movement, in addition, a movement is perpendicular to the x-y plane and thus in the z-direction. In this case, on the one hand, a movement of the ultrasonic actuator relative to the friction surface is possible; On the other hand, it is also conceivable that the ultrasonic actuator is fixed and causes a relative movement of the element which forms the friction surface.

It may be advantageous that the excitation electrodes on the outer peripheral surface of the Ultrasonic actuator and the general electrode or the general electrodes are arranged on the inner peripheral surface of the ultrasonic actuator.

Likewise, it may be advantageous that the excitation electrodes, the general electrodes and the respective layers of piezoceramic arranged between them are arranged substantially parallel to the end faces of the ultrasound actuator.

Furthermore, it can be advantageous for the electrical exciter device to provide an alternating electrical voltage with a frequency at which the sixth mode of the acoustic standing wave is generated in the ultrasound actuator.

In this case, it may be advantageous that the ultrasonic motor includes a switch for the electrodes, which connects them with the electrical excitation device that when generating the sixth mode of the acoustic standing wave in the ultrasonic actuator at a pair of diametrically opposed friction elements, the maximum deflection occurs on or along the inclined trajectory and the other pair of diametrically opposed friction elements, the minimum deflection occurs on or along the inclined trajectory.

Brief description of the drawings:

1 : Ultrasonic motor according to the invention (without representation of the electrical excitation device)

2 : Presentation 8th : Ultrasonic actuator of the ultrasonic motor according to 1 in perspective view; presentation 9 : Ultrasonic actuator of the ultrasonic motor according to 1 in plan view (view from above)

3 : Embodiment of an Ultrasonic Actuator of an Ultrasonic Motor According to the Invention (Without Depiction of the Friction Elements)

4 : Block diagram relating to the connection of the ultrrachound actuator of an ultrasonic motor according to the invention with the electrical excitation device

5 : Presentation 28 : FEM model of an ultrasonic actuator of an ultrasonic motor according to the invention in the unexcited state; representations 27 and 29 : FEM calculations of the phases of maximum deformation based on the model as shown 28

6 : Representations 33 to 38 : Influence of the Different Electrical Control of an Ultrasonic Actuator of an Ultrasonic Motor According to the Invention on the Direction of Deflection of the Friction Elements

7 : Contact or engagement situation between a friction element of an ultrasonic actuator of an ultrasonic motor according to the invention and a friction surface

1 shows an ultrasonic motor according to the invention, comprising an ultrasonic actuator 1 , which is a wave resonator 2 forms, wherein the ultrasonic actuator as a hollow cylinder 3 is made of a piezoelectric material, and on which a flat end face 5 four friction elements 4 are arranged. The ultrasound actuator 1 is by a force F with its friction elements 4 elastic to the friction surface 6 a friction table 7 pressed. The force F may be caused by the gravity of the ultrasonic actuator, but it may also be caused by an additional element, such as a spring or a magnet.

presentation 8th from 2 shows the ultrasonic actuator according to 1 as a single item. The ultrasonic actuator has a total of twelve equal circumferential sections or peripheral segments 10 on. Each peripheral section 10 includes an excitation electrode 11 , wherein the excitation electrodes of adjacent peripheral sections 10 do not touch. On the inner peripheral surface 14 The ultrasound actuator is a completely circumferential general electrode 13 arranged. Each excitation electrode 11 forms with the corresponding opposite portion of the general electrode 13 and the layer of piezoelectric material disposed between the two electrodes comprises a generator for an acoustic standing wave or deformation wave to be formed in the ultrasonic actuator. On the flat face 5 are four friction elements 4 arranged, wherein the friction elements are each arranged in the region of the middle between two adjacent exciter electrodes. In other words, the symmetry line of each friction element runs in the middle between two neighboring exciter electrodes. Two adjacent friction elements 4 include a circumferential angle of substantially 90 ° so that there are two pairs of friction elements in which the two corresponding friction elements are arranged diametrically opposite one another.

Based on presentation 9 from 2 , which the ultrasound actuator as shown 8th In plan view, the geometric relationships between the individual elements of the ultrasonic actuator are particularly well visible. Through the cylinder or the circle of the cylinder can be numerous diametrical planes S set (dash-dotted lines), which either run respectively through the middle between two adjacent excitation electrodes, or which the planes of symmetry of the friction elements represent. The diametrical planes S divide the hollow cylinder into twelve equal circumferential sections 10 , In presentation 8th from 2 as well as in the corresponding other figures are the intersections of the diametral planes S with the ultrasonic actuator 1 marked by dotted lines.

Furthermore, by illustration 9 from 2 the polarization direction of the piezoceramic layer 15 indicated by the corresponding arrows with the index p. The polarization direction here is oriented normal to the electrodes, so that a radially directed polarization results. In addition, presentation shows 9 from 2 the electrical connections A1 to A12 of the excitation electrodes and the electrical connection A0 of the general electrode.

3 shows an alternative embodiment for an ultrasonic actuator of an ultrasonic motor according to the invention. In this lie for each generator several layers of exciter electrodes 11 and general electrodes 13 in an alternating arrangement, wherein between the electrode layers layers of piezoceramic material 15 are arranged (so-called multilayer arrangement). The layers are in this case stacked in the axial direction of the ultrasonic actuator, and the polarization direction of the piezoceramic material is normal to the electrodes or normal to the end faces, ie in the axial direction, the polarization directions of each adjacent layers of piezoelectric material are opposite (antiparallel polarization direction). All excitation electrodes 11 of the respective generator are contacted by the respective terminal A1 to A12, while all general electrodes 13 the respective generator via the terminal A0 are contacted.

4 shows a block diagram relating to the connection of the ultrasonic actuator of an ultrasonic motor according to the invention with the electrical excitation device 16 , The corresponding electrical circuit in this case comprises a switch 20 which is the circuit breaker 21 to 26 includes, by means of which a connection between the electrical excitation device and the excitation electrodes to be controlled can be realized. Here is the circuit breaker 21 connected to the terminals A1, A4, A5, A8, A9 and A12, the off switch 22 is connected to the terminals A2, A3, A6, A7, A10 and A11, etc.

The electrical excitation device 16 puts on their connections 17 and 18 the electrical AC voltage U1, and at the terminals 19 and 18 the electrical AC voltage U2 ready. These voltages are mutually phase-shifted by the angle 180 °. They have the same frequency fo, which means in the ultrasonic actuator 1 the sixth mode of the acoustic deformation standing wave (six half waves with λ / 2) is excited or generated. Each of the generators generates a λ / 4 portion of the standing wave.

5 shows in presentation 28 the FEM model of an ultrasonic actuator of an ultrasonic motor according to the invention in the unexcited state, while the representations 27 and 29 FEM calculations based on the model as shown 28 show the phases of maximum deformation due to the excited in the ultrasonic actuator standing wave. This standing wave is activated by pressing any switch 21 to 26 generated. The points on the crests of the standing wave 30 the face 5 have only a transverse or axial component of the vibrations. The points lying on the sloping sections of the standing wave 31 the face 5 on the other hand have both a transverse or axial component, as well as a longitudinal or tangential component of the vibrations.

Press any switch 21 to 26 does not change the shape of the generated standing wave. It only changes the position of the shaft with respect to the friction elements 4 , The displacement of the shaft is either half a wavelength, ie λ / 2, or one quarter of the wavelength, ie λ / 4.

The change in the shaft position described above has a change in the trajectory of the points 32 the friction elements 4 as in the illustrations 33 to 38 from 6 is shown.

presentation 33 corresponds to the position switch off 21 switched on.

presentation 34 corresponds to the position off switch 22 switched on.

presentation 35 corresponds to the position off switch 23 switched on.

presentation 36 corresponds to the position off switch 24 switched on.

presentation 37 corresponds to the position off switch 25 switched on.

presentation 38 corresponds to the position off switch 26 switched on.

In all cases, the points move 32 on two different trajectories, namely on the inclined trajectory 40 and the transverse trajectory 41 ,

7 clarifies the movement of the points 32 the friction elements 4 on the inclined trajectory 40 , The inclined trajectory 40 can be decomposed into two components, namely a longitudinal or tangential component 42 and a transverse or axial component 43 , The longitudinal component 42 the trajectory causes the friction element 5 the actor 1 in the with arrow 44 shown direction (drive direction).

Which are on the transverse trajectory 41 moving points 32 have no longitudinal motion component, which is why they do not affect the movement of the actuator 1 to have.

Pressing the off switch 21 to 26 leads to a change in the trajectory of the points 32 , by a transverse trajectory 41 to an inclined trajectory 40 and to that in the representations 33 to 38 from 6 shown reversal of the inclination angle of the trajectory 40 , This reversal of the inclination angle of the trajectory 40 leads to a reversal of movement (see also the in 1 with the six arrows 44 illustrated change of the movement of the actuator 1 on the friction table 7 ).

By pressing the switch 21 to 26 is a linear movement of the actuator 1 on the friction surface 6 possible, and forward (as shown 33 from 6 ) backwards (as shown 34 from 6 ), to the right (as shown 35 from 6 ) and to the left (as shown 36 from 6 ). Furthermore, a rotary movement in a clockwise direction (as shown 37 from 6 ) or counterclockwise (as shown 38 from 6 ) possible.

The invention enables a constructive design of the ultrasonic motor, in which the ultrasonic actuator 1 is attached, which is arranged in guides friction table 7 set in motion, with the guides leading to the faces 5 of the actor 1 limit vertical movement (not shown in the figures).

Claims (5)

An ultrasonic motor comprising a piezoelectric ultrasonic actuator ( 1 ) with four friction elements ( 4 ), a friction surface ( 6 ) in frictional contact with the friction elements, and an electrical excitation device ( 16 ), wherein the ultrasonic actuator takes the form of a ring or a hollow cylinder with an inner peripheral surface ( 14 ), an outer peripheral surface ( 12 ) and two the inner and the outer peripheral surface connecting planar end faces ( 5 ), wherein the four friction elements are arranged on one of the end faces of the ultrasonic actuator in equidistant with respect to the circumferential direction distance, so that in each case two of the friction elements are diametrically opposite, and the ultrasonic actuator twelve equal peripheral portions ( 10 ), each of which has a generator for an acoustic standing wave to be formed in the ultrasonic actuator, and the deformations of the ultrasonic actuator caused by the standing wave lead to deflections of the friction elements on a trajectory inclined to the face and / or a trajectory substantially perpendicular to the face, and each generator at least one exciter electrode ( 11 ), at least one general electrode ( 13 ) or a section of a general electrode and a layer of piezoceramic material arranged between the excitation electrode and the general electrode or the section of the general electrode ( 15 ) having. An ultrasonic motor according to claim 1, characterized in that the excitation electrodes are arranged on the outer peripheral surface of the ultrasonic actuator and the general electrode or the general electrodes on the inner peripheral surface of the ultrasonic actuator. Ultrasonic motor according to claim 1, characterized in that the exciter electrodes, the general electrodes and the respectively arranged therebetween layers of piezoceramic are arranged substantially parallel to the end faces of the ultrasonic actuator. Ultrasonic motor according to one of the preceding claims, characterized in that the electrical exciter device provides an alternating electrical voltage with a frequency at which the sixth mode of the acoustic standing wave is generated in the ultrasonic actuator. Ultrasonic motor according to claim 4, characterized in that this a switch ( 20 ) for the electrodes connecting them to the electrical excitation device such that when the sixth mode of the acoustic standing wave is generated in the ultrasonic actuator for a pair of diametrically opposed friction elements, the maximum deflection occurs along the inclined trajectory and for the other pair diametrically opposed friction elements the minimum deflection occurs along the inclined trajectory.

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